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Dinosaur Incubation Periods Directly Determined from Growth-Line Counts in Embryonic Teeth Show Reptilian-Grade Development

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Dinosaur Incubation Periods Directly Determined from Growth-Line Counts in Embryonic Teeth Show Reptilian-Grade Development Dinosaur incubation periods directly determined from growth-line counts in embryonic teeth show reptilian-grade development Gregory M. Ericksona,1, Darla K. Zelenitskyb, David Ian Kaya, and Mark A. Norellc aDepartment of Biological Science, Florida State University, Tallahassee, FL 32306-4295; bDepartment of Geoscience, University of Calgary, Calgary, AB, Canada T2N 1N4; and cDivision of Paleontology, American Museum of Natural History, New York, NY 10024 Edited by Neil H. Shubin, University of Chicago, Chicago, IL, and approved December 1, 2016 (received for review August 17, 2016) Birds stand out from other egg-laying amniotes by producing anatomical, behavioral and eggshell attributes of birds related to relatively small numbers of large eggs with very short incubation reproduction [e.g., medullary bone (32), brooding (33–36), egg- periods (average 11–85 d). This aspect promotes high survivorship shell with multiple structural layers (37, 38), pigmented eggs (39), by limiting exposure to predation and environmental perturba- asymmetric eggs (19, 40, 41), and monoautochronic egg pro- tion, allows for larger more fit young, and facilitates rapid attain- duction (19, 40)] trace back to their dinosaurian ancestry (42). For ment of adult size. Birds are living dinosaurs; their rapid development such reasons, rapid avian incubation has generally been assumed has been considered to reflect the primitive dinosaurian condition. throughout Dinosauria (43–45). Here, nonavian dinosaurian incubation periods in both small and Incubation period estimates using regressions of typical avian large ornithischian taxa are empirically determined through growth- values relative to egg mass range from 45 to 80 d across the line counts in embryonic teeth. Our results show unexpectedly slow known 0.42- to 5.63-kg dinosaurian egg-size spectrum (43). incubation (2.8 and 5.8 mo) like those of outgroup reptiles. Develop- Similar estimates have resulted using alternative methods [e.g., mental and physiological constraints would have rendered tooth for- 31–77 d across the dinosaurian size spectrum using estimates of mation and incubation inherently slow in other dinosaur lineages and adult and hatchling size and assuming avian embryonic metab- basal birds. The capacity to determine incubation periods in extinct olism (45) and 65–82 d for large (1.62–5.08 kg) sauropod eggs egg-laying amniotes has implications for dinosaurian embryology, life using avian clutch mass to adult size ratios and avian incubation history strategies, and survivorship across the Cretaceous–Paleogene rates (46)]. [Note: The possibility that sauropods showed in- mass extinction event. cubation rates like members of the Crocodylia (the extant sister clade to Dinosauria) was explored in the latter study. However, Dinosauria | teeth | embryology | Neornithes | extinction this also predicts rapid values (68–71 d) because the regression line for crocodilians intercepts avian rates when extrapolated out keletal growth series afford considerable understanding about to the grossly larger sauropod egg sizes.] Sposthatchling development in nonavian dinosaurs (hereafter Direct determination of dinosaurian incubation duration has dinosaurs) (1, 2). Nevertheless, very little is known about their been considered intractable (43, 47). However, in crocodilian embryology. An important parameter that can provide myriad (48) and human (49) embryonic teeth, incremental lines of insights into dinosaurian in ovo development is incubation period. von Ebner that reflect diurnal pulses of mineralization during This ontogenetic measure is relevant to the timing of developmental odontogenesis are present. Counts of these markers have been milestones (e.g., formation of eyes, teeth, brain, and so forth) (3–5), mortality risks (6–9), egg and clutch sizes (10–12), fecundity and Significance lifespan (13), reproductive effort (14), altricial vs. precocial de- velopmental modes (5, 15), parental attentiveness (13, 16), en- Little is known regarding nonavian dinosaur embryology. Em- vironmental and genetic influences affecting development (11, bryological period relates to myriad aspects of development, 12, 17), migration (18), environmental restrictions on breeding life history, and evolution. In reptiles incubation is slow, seasons (13, 14), and so forth. whereas in birds it is remarkably rapid. Because birds are living Incubation periods differ substantially among extant nonavian dinosaurs, rapid incubation has been assumed for all dinosaurs. reptiles (Lepidosauria, Testudines, Crocodylia; hereafter rep- We discovered daily forming growth lines in teeth of embry- tiles) (11) and birds (Neornithes) (10, 12). Most reptiles have two onic nonavian dinosaurs revealing incubation times. These lines functional oviducts, and the eggs of an entire clutch are formed show slow reptilian-grade development spanning months. The – then laid at the same time (19 21). The eggs typically hatch over rapid avian condition likely evolved within birds prior to the considerably longer time periods than same-sized avian eggs (12, Cretaceous–Paleogene (K–Pg) mass extinction event. Prolonged 22). Birds, on the other hand, typically have a single functional incubation exposed nonavian dinosaur eggs and attending par- ovary and lay fewer, but relatively larger eggs than reptiles (23). ents to destructive influences for long periods. Slow develop- In amniotes, egg size positively correlates with incubation period ment may have affected their ability to compete with more – (10 12). This should be a negative effect because of extended rapidly generating populations of birds, reptiles, and mammals – exposure of eggs to destructive influences (6, 24 26). Birds following the K–Pg cataclysm. generally mitigate these costs with short incubation periods made possible by elevated and relatively stable nest temperatures Author contributions: G.M.E. and D.K.Z. designed research; G.M.E., D.K.Z., and M.A.N. per- (through brooding or environmental heat sources) (27, 28), ef- formed research; G.M.E., D.K.Z., and D.I.K. analyzed data; and G.M.E., D.K.Z., and M.A.N. ficient gas conductance through the eggshell (29), and high wrote the paper. embryonic metabolic and growth rates (22). The authors declare no conflict of interest. Birds are members of Sauria, which includes extant nonavian This article is a PNAS Direct Submission. reptiles showing characteristically long incubation periods. How- Freely available online through the PNAS open access option. ever, they are also living dinosaurs (Dinosauria) (30, 31), with 1To whom correspondence should be addressed. Email: [email protected]. extant forms showing rapid incubation. Phylogenetically, either This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10. condition is plausible for their dinosaurian ancestors. A number of 1073/pnas.1613716114/-/DCSupplemental. 540–545 | PNAS | January 17, 2017 | vol. 114 | no. 3 www.pnas.org/cgi/doi/10.1073/pnas.1613716114 used to determine tooth formation times in postparturition mam- mals (50, 51), and replacement rates in posthatchling crocodilians (52) and dinosaurs (53, 54). This finding prompted us to explore the possibility that these time markers exist in embryonic dinosaur teeth and could be used to determine incubation period. Here we: (i) show that incremental lines of von Ebner are present in embryonic dinosaur teeth; (ii) use increment counts and data on tooth initiation in reptiles to reveal incubation pe- riod in two ornithischian dinosaurs (Protoceratops andrewsi and Hypacrosaurus stebingeri), whose eggs span nearly the entire size range reported for dinosaurs; (iii) test whether these dinosaurs show typical rapid avian incubation times or primitive slow reptilian development; and (iv) explore ramifications of our re- sults with regard to the origin of the modern avian condition, dinosaurian life history, and survivorship through the Creta- ceous–Paleogene (K–Pg) extinction event. Results Mean von Ebner incremental line width for embryonic P. andrewsi is 10.04 μm(n = 20; range 9.05–13.92 μm) and 15.26 μm(n = 15; range 9.42–16.62 μm) for H. stebingeri (Fig. 1 A and B). Mean replacement rates for embryonic P. andrewsi teeth are 30.68 d (n = 2 tooth families; 31.19 and 30.18 d) and 44.18 d for embryonic H. stebingeri teeth (n = 3 tooth families; 43.22, 43.48, and 45.83 d) (Materials and Methods and Fig. S1) Fig. 1. Daily growth lines in embryonic dinosaur teeth and CT rendering of ’ Near-term P. andrewsi embryos (Fig. 2 A and B) show tooth a P. andrewsi jaw and tooth family. (A) Von Ebner s growth lines (alternating dark and light bands) in the orthodentine surrounding the pulp cavity (at families composed of two teeth: one that is functional and the top of graphic) of an embryonic H. stebingeri tooth (polarized microscopy, other a replacement (Fig. 1C and 2C and Fig. S1).Thetimeelapsed transverse view). (B) Von Ebner’s growth lines surrounding the pulp cavity in forming the oldest tooth in the dentition, determined from the (at top of the graphic) in an embryonic tooth of P. andrewsi (polarized mi- total number of incremental lines represented in the tooth, is 48.23 d. croscopy, transverse view). (C) High-resolution CT rendition of a P. andrewsi As described below (Materials and Methods), hatchling teeth were tooth family within the jaw used to determine tooth-formation times in conservatively modeled as initiating at 42% of the incubation period embryonic teeth. (34.93 d). The sum of these values reveals a minimum incubation period of 83.16 d for the P. andrewsi embryo. The near-term H. stebingeri embryos show tooth families com- Discussion posed of three teeth: two that are functional and a single re- Discovery of von Ebner incremental lines in embryonic dinosaur placement (Fig. 2D and Fig. S1). The oldest functional tooth is just a teeth provides direct empirical estimates for their incubation root remnant, so its formation time could not be directly determined periods. This opens the door to tracing the genesis of rapid avian from a total growth-line count because of the loss of increments in ovo development and provides some of the first empirical present only in the tooth crown.
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